Multiports and optical connectors with rotationally discrete locking and keying features

ABSTRACT

Fiber optic connectors and connectorized fiber optic cables include connector housings having locking portions defined on the connector housing that allow the connector housing to be selectively coupled to a corresponding push-button securing member of a multiport assembly. Methods for selectively connecting a fiber optic connector to, and disconnecting the fiber optic connector from the multiport assemblies allow for connector housings to be forcibly and nondestructively removed from the multiport assembly.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.16/516,551 filed on Jul. 19, 2019, which is a continuation of U.S.patent application Ser. No. 16/018,988 filed on Jun. 26, 2018 which isnow U.S. patent Ser. No. 10/359,577 granted on Jul. 23, 2019, which is acontinuation-in-part of PCT/US2017/064072 filed Nov. 30, 2017, andclaims the benefit of U.S. Provisional Patent Application 62/526,011,filed on Jun. 28, 2017, U.S. Provisional Patent Application 62/526,018filed on Jun. 28, 2017, and U.S. Provisional Patent Application62/526,195 filed on Jun. 28, 2017, the contents each of which are herebyincorporated by reference in their entirety.

BACKGROUND Field

The present disclosure relates generally to assemblies forinterconnecting or otherwise terminating optical fibers and fiber opticcables in a manner suitable for mating with corresponding opticalreceptacles.

Technical Background

Optical fibers are used in an increasing number and variety ofapplications, such as a wide variety of telecommunications and datatransmission applications. As a result, fiber optic networks include anever increasing number of terminated optical fibers and fiber opticcables that can be conveniently and reliable mated with correspondingoptical receptacles in the network. These terminated optical fibers andfiber optic cables are available in a variety of connectorized formatsincluding, for example, hardened OptiTap® and OptiTip® connectors,field-installable UniCam® connectors, preconnectorized single ormulti-fiber cable assemblies with SC, FC, or LC connectors, etc, all ofwhich are available from Corning Incorporated, with similar productsavailable from other manufacturers, as is well documented in the patentliterature.

The optical receptacles with which the aforementioned terminated fibersand cables are coupled are commonly provided at optical network units(ONUS), network interface devices (NIDs), and other types of networkdevices or enclosures, and often require hardware that is sufficientlyrobust to be employed in a variety of environments under a variety ofinstallation conditions. These conditions may be attributable to theenvironment in which the connectors are employed, or the habits of thetechnicians handling the hardware. Consequently, there is a continuingdrive to enhance the robustness of these connectorized assemblies, whilepreserving quick, reliable, and trouble-free optical connection to thenetwork.

BRIEF SUMMARY

Fiber optic connectors, connectorized cable assemblies, multiportassemblies, and methods for connecting fiber optic connectors to, anddisconnecting fiber optic connectors from multiport assemblies aredisclosed herein.

In one embodiment, a fiber optic connector includes a ferrule includingan optical fiber bore and a connector housing, where the connectorhousing includes a ferrule retaining portion positioned at a frontportion of the connector housing, the ferrule retaining portionstructurally configured to engage and retain the ferrule, a longitudinalaxis extending from the front portion of the connector housing, throughthe ferrule retaining portion to a rear portion of the connector housingpositioned opposite the front portion, a nominal housing portion definedon an outer surface of the connector housing, and a locking portiondefined on the outer surface of the connector housing and interruptingthe nominal housing portion, where the locking portion includes a portengagement face that extends inward from the nominal housing portion ofthe connector housing toward the longitudinal axis and that is orientedtransverse to the longitudinal axis, and the locking portion furtherincludes a locking portion recess positioned rearward of the portengagement face and inward of the nominal housing portion of theconnector housing, and the locking portion recess is oriented transverseto the port engagement face and includes a planar surface extendingacross at least a portion of the outer surface of the connector housing.

In another embodiment, a connectorized fiber optic cable includes aferrule including an optical fiber bore and a connector housingincluding a ferrule retaining portion positioned at a front portion ofthe connector housing, the ferrule retaining portion engaged with theferrule, a longitudinal axis extending from the front portion of theconnector housing, through the ferrule retaining portion and the opticalfiber bore of the ferrule to a rear portion of the connector housingpositioned opposite the front portion, a nominal housing portion definedon an outer surface of the connector housing, and a locking portiondefined on the outer surface of the connector housing and interruptingthe nominal housing portion, where the locking portion includes a portengagement face that extends inward from the nominal housing portion ofthe connector housing toward the longitudinal axis and that is orientedtransverse to the longitudinal axis, and the locking portion furtherincludes a locking portion recess positioned rearward of the portengagement face and inward of the nominal housing portion of theconnector housing, and the locking portion recess is oriented transverseto the port engagement face and includes a planar surface extendingacross at least a portion of the outer surface of the connector housing,and a fiber optic cable including an optical fiber extending along thelongitudinal axis of the connector housing to the optical fiber bore ofthe ferrule.

In yet another embodiment, a multiport assembly includes a shelldefining a cavity positioned within the shell, a plurality of opticaladapters positioned within the cavity of the shell, the plurality ofoptical adapters structurally configured to receive, align, andoptically couple dissimilar optical connectors, a plurality of opticalconnector ports including respective connection port passagewayspermitting external optical connectors to access the plurality ofoptical adapters positioned within the cavity of the shell, theconnection port passageways including respective connector insertionpaths, and a plurality of push-button securing members associated withrespective ones of the connection port passageways, each push-buttonsecuring member of the plurality of push-button securing membersincluding a bore extending through the push-button securing member, thebore defining an inner perimeter, a connector engagement face positionedon the bore and oriented transverse to a corresponding connectorinsertion path, the connector engagement face including an inner end andan outer end positioned outward of the inner end, and a ramp positionedon the bore, the ramp extending between the inner perimeter of the boreand the inner end of the connector engagement face.

In yet another embodiment, a fiber optic junction includes a multiportassembly includes a shell defining a cavity positioned within the shell,an optical adapter positioned within the cavity of the shell, theoptical adapter structurally configured to receive, align, and opticallycouple dissimilar optical connectors, an optical connection port definedby the shell and in communication with the cavity, the opticalconnection port includes a connection port passageway extending into thecavity and defining a connector insertion path, and a push-buttonsecuring member that intersects the connection port passageway, thepush-button securing member including a bore extending through thepush-button securing member and defining an inner perimeter, and aconnector engagement face extending inward from the inner perimeter ofthe bore, and a fiber optic connector positioned at least partiallywithin the connector insertion path of the multiport assembly, the fiberoptic connector including a connector housing including a ferruleretaining portion positioned at a front portion of the connectorhousing, the ferrule retaining portion structurally configured to engageand retain a ferrule, a longitudinal axis extending from the frontportion of the connector housing, through the ferrule retaining portionto a rear portion of the connector housing positioned opposite the frontportion, a nominal housing portion defined on an outer surface of theconnector housing, and a locking portion defined on the outer surface ofthe connector housing and interrupting the nominal housing portion,where the locking portion includes a port engagement face that extendsinward from the nominal housing portion of the connector housing towardthe longitudinal axis and that is oriented transverse to thelongitudinal axis, and the locking portion further includes a lockingportion recess positioned rearward of the port engagement face andinward of the nominal housing portion of the connector housing, and thelocking portion recess is oriented transverse to the port engagementface and includes a planar surface extending across at least a portionof the outer surface of the connector housing, and where the portengagement face is selectively engaged with the connector engagementface of the multiport assembly.

In yet another embodiment, a method for selectively connecting a fiberoptic connector to a multiport assembly includes inserting a connectorhousing of a fiber optic connector into a connector port of a multiportassembly, the connector housing including a longitudinal axis extendingthrough the connector housing, engaging a ramp of a push-button securingmember of the multiport assembly with the connector housing, moving thepush-button securing member away from a connector insertion path definedby the multiport assembly, moving at least a portion of the connectorhousing through a bore of the push-button securing member of themultiport assembly, moving at least a portion of the push-buttonsecuring member into a locking portion recess of the connector housing,and engaging a connector engagement face of the push-button securingmember that is oriented transverse to the connector insertion path ofthe multiport assembly, with a port engagement face of the connectorhousing that is oriented transverse to the longitudinal axis of theconnector housing to selectively couple the connector housing to themultiport assembly.

In yet another embodiment, a fiber optic connector includes a ferruleand a connector housing, where the ferrule includes an optical fiberbore and the connector housing includes a ferrule retaining portionstructurally configured to engage and retain the ferrule at a frontportion of the connector housing, a longitudinal axis extending from aleading edge plane of the front portion of the connector housing,through the ferrule retaining portion, to a rear portion of theconnector housing, a nominal housing portion defined on an outer surfaceof the connector housing, a rotationally discrete keying portion definedon the outer surface of the connector housing, and a rotationallydiscrete locking portion defined on the outer surface of the connectorhousing, where the nominal housing portion is interrupted by therotationally discrete keying portion and the rotationally discretelocking portion, the connector housing has an unobstructed line of sightfrom the rotationally discrete keying portion to the leading edge planeof the connector housing along an advancing direction of the fiber opticconnector, the rotationally discrete keying portion includes at leastone rotationally discrete contact surface that is structurallyconfigured to inhibit rotation of the connector housing about thelongitudinal axis when engaged with a complementary keying portion of anoptical connector port, the rotationally discrete locking portionincludes a rearwardly facing port engagement face and a locking portionrecess that is positioned rearward of the port engagement face, thelocking portion recess is obstructed from the leading edge plane of theconnector housing along the advancing direction of the fiber opticconnector by the port engagement face, and the port engagement face ofthe locking portion is structurally configured to inhibit axial movementof the connector housing along a retracting direction of the fiber opticconnector when engaged with a complementary securing member of anoptical connector port.

In yet another embodiment, a multiport assembly includes a shelldefining a cavity positioned within the shell, a plurality of opticaladapters positioned within the cavity of the shell, the optical adaptersstructurally configured to receive, align, and optically coupledissimilar optical connectors, a plurality of optical connector portsincluding respective connection port passageways permitting externaloptical connectors to access the plurality of optical adapterspositioned within the cavity of the shell, the connection portpassageways including corresponding connector insertion paths, aplurality of rotationally discrete keying portions associated withrespective ones of the connection port passageways, where each keyingportion includes at least one rotationally discrete contact surface inunobstructed line of sight with an open end of a respective connectionport passageway and the at least one rotationally discrete contactsurface is structurally configured to inhibit rotation of a connectorhousing residing in the respective connection port passageway, and aplurality of push-button securing members associated with respectiveones of the connection port passageways, where each push-button securingmember is biased in an engaged position, in which a rotationallydiscrete locking portion of the push-button securing member ispositioned within the corresponding connector insertion path, and isselectively positionable into and out of a disengaged position, in whichthe rotationally discrete locking portion of the push-button securingmember is positioned outside the corresponding connector insertion path,the rotationally discrete locking portion of each push-button securingmember includes a ramp oriented to progressively constrict thecorresponding connector insertion path along an advancing direction of afiber optic connector in the respective connection port passageway andan locking portion recess obstructed from the open end of the respectiveconnection port passageway by a connector engagement face of therotationally discrete locking portion of the push-button securingmember, and the connector engagement face of the rotationally discretelocking portion is structurally configured to inhibit axial movement ofa fiber optic connector in the connection port passageway along aretracting direction of a fiber optic connector in the respectiveconnection port passageway.

In yet another embodiment, a method for connecting a fiber opticconnector to a multiport assembly includes providing a fiber opticconnector including a ferrule and a connector housing, where the ferruleincludes an optical fiber bore and the connector housing includes aferrule retaining portion structurally configured to engage and retainthe ferrule at a front portion of the connector housing, a longitudinalaxis extending from a leading edge plane of the front portion of theconnector housing, through the ferrule retaining portion to a rearportion of the connector housing, a nominal housing portion defined onan outer surface of the connector housing, a rotationally discretekeying portion defined on the outer surface of the connector housing,and a rotationally discrete locking portion defined on the outer surfaceof the connector housing, where the nominal housing portion isinterrupted by the rotationally discrete keying portion and the lockingportion, the rotationally discrete keying portion includes anunobstructed line of sight with the leading edge plane of the connectorhousing along an advancing direction of the fiber optic connector, therotationally discrete keying portion including at least one rotationallydiscrete contact surface structurally configured to inhibit rotation ofthe connector housing about the longitudinal axis when engaged with acomplementary keying portion of an optical connector port, the lockingportion includes a rearwardly facing port engagement face and a lockingportion recess that is positioned rearward of the port engagement face,the locking portion recess is obstructed from the leading edge plane ofthe connector housing along the advancing direction of the fiber opticconnector by the port engagement face, and the port engagement face ofthe locking portion is structurally configured to inhibit axial movementof the connector housing along a retracting direction of the fiber opticconnector when engaged with a complementary locking portion of anoptical connector port, advancing the fiber optic connector along theadvancing direction into an optical connector port of a multiportassembly including a plurality of optical adapters, the optical adaptersstructurally configured to receive, align, and optically couple thefiber optic connector with a dissimilar optical connector within themultiport assembly, aligning the rotationally discrete keying portion ofthe connector housing with a complementary rotationally discrete keyingportion associated with the optical connector port to permit therotationally discrete locking portion of the connector housing to engagea rotationally discrete locking portion of a push-button securing memberassociated with the optical connector port, and engaging therotationally discrete locking portion of the connector housing with therotationally discrete locking portion of the push-button securing memberassociated with the optical connector port.

In yet another embodiment, a connectorized fiber optic cable assemblyincludes a ferrule, a connector housing, a cable adapter, a fiber opticcable, and a type SC conversion housing, where the connector housingincludes a ferrule retaining portion, an adapter seating portion, alongitudinal axis extending transversely from a leading edge plane ofthe front portion of the connector housing, through the ferruleretaining portion and the adapter seating portion of the connectorhousing, to a rear portion of the connector housing, a rotationallydiscrete keying portion defined on the outer surface of the connectorhousing, a rotationally discrete locking portion defined on the outersurface of the connector housing, and a nominal housing portion definedon an outer surface of the connector housing and interrupted by thekeying portion and the locking portion of the connector housing, theferrule comprises a 2.5 millimeter nominal ferrule diameter, is retainedby the ferrule retaining portion of the connector housing, and comprisesan optical fiber bore, the keying portion of the connector housingcomprises at least one rotationally discrete contact surface that isstructurally configured to inhibit rotation of the connector housingabout the longitudinal axis when engaged with a complementary keyingportion of an optical connector port, the locking portion of theconnector housing includes a rearwardly facing port engagement face anda locking portion recess that is positioned rearward of the portengagement face, the locking portion recess of the locking portion isobstructed from the leading edge plane of the connector housing alongthe advancing direction of the fiber optic connector by the portengagement face, the port engagement face of the locking portion isstructurally configured to inhibit axial movement of the connectorhousing along a retracting direction of the fiber optic connector whenengaged with a complementary locking portion of an optical connectorport, the cable adapter comprises an optical cable passageway, anoptical fiber passageway, a housing insert portion seated in the adapterseating portion of the connector housing to align the optical cablepassageway and the optical fiber passageway with the longitudinal axisof the connector housing, and an adapter abutment limiting an extent towhich the cable adapter extends into the adapter seating portion of theconnector housing, the fiber optic cable extends along the optical cablepassageway of the cable adapter and comprises an optical fiber extendingalong optical fiber passageway of the cable adapter and the opticalfiber bore of the ferrule, and the connector housing comprises a line ofsight from the keying portion to the leading edge plane of the connectorhousing that is obstructed only by the type SC conversion housing alongan advancing direction of the fiber optic connector.

In yet another embodiment, a connectorized fiber optic cable assemblyincludes a ferrule, a connector housing, a cable adapter, a fiber opticcable, and a hardened conversion housing, where the connector housingincludes a ferrule retaining portion, an adapter seating portion, alongitudinal axis extending transversely from a leading edge plane ofthe front portion of the connector housing, through the ferruleretaining portion and the adapter seating portion of the connectorhousing, to a rear portion of the connector housing, a rotationallydiscrete keying portion defined on the outer surface of the connectorhousing, a rotationally discrete locking portion defined on the outersurface of the connector housing, and a nominal housing portion definedon an outer surface of the connector housing and interrupted by thekeying portion and the locking portion of the connector housing, theferrule includes a 2.5 millimeter nominal ferrule diameter, is retainedby the ferrule retaining portion of the connector housing, and includesan optical fiber bore, the keying portion of the connector housingincludes at least one rotationally discrete contact surface that isstructurally configured to inhibit rotation of the connector housingabout the longitudinal axis when engaged with a complementary keyingportion of an optical connector port, the locking portion of theconnector housing includes a rearwardly facing port engagement face anda locking portion recess that is positioned rearward of the portengagement face, the locking portion recess of the locking portion isobstructed from the leading edge plane of the connector housing alongthe advancing direction of the fiber optic connector by the portengagement face, the port engagement face of the locking portion isstructurally configured to inhibit axial movement of the connectorhousing along a retracting direction of the fiber optic connector whenengaged with a complementary locking portion of an optical connectorport, the cable adapter including an optical cable passageway, anoptical fiber passageway, a housing insert portion seated in the adapterseating portion of the connector housing to align the optical cablepassageway and the optical fiber passageway with the longitudinal axisof the connector housing, and an adapter abutment limiting an extent towhich the cable adapter extends into the adapter seating portion of theconnector housing, the fiber optic cable extends along the optical cablepassageway of the cable adapter and includes an optical fiber extendingalong optical fiber passageway of the cable adapter and the opticalfiber bore of the ferrule, the hardened conversion housing including apair of opposing fingers including opposing interior faces that extendparallel to, and are arranged symmetrically about, the longitudinal axisof the connector housing, a finger spacing between the opposing interiorfaces of the opposing fingers is between 10.80 millimeters and 10.85millimeters, a finger depth along a direction parallel to thelongitudinal axis of the connector housing is between 8.45 millimetersand 8.55 millimeters, a finger width along a direction perpendicular tothe finger depth and the longitudinal axis of the connector housing isless than 10 millimeters, outer faces of the opposing fingers lie alonga common outside diameter of between 15.75 millimeters and 15.85millimeters, an outer face of one of the opposing fingers is truncatedin a plane parallel to the opposing interior faces to define a truncatedspan of between about 14.75 millimeters and about 14.95 millimeters,extending from the outer face of the truncated opposing finger to theouter face of the opposite finger, and the connector housing includes aline of sight from the keying portion to the leading edge plane of theconnector housing that is obstructed only by the hardened conversionhousing along an advancing direction of the fiber optic connector.

In yet another embodiment, a connectorized fiber optic cable assemblyincludes a ferrule, a connector housing, a cable adapter, a fiber opticcable, and a type SC conversion housing, where the connector housingincludes a ferrule retaining portion positioned at a front portion ofthe connector housing, an adapter seating portion, a longitudinal axisextending transversely from a leading edge plane of the front portion ofthe connector housing, through the ferrule retaining portion and theadapter seating portion of the connector housing, to a rear portion ofthe connector housing, a nominal housing portion defined on an outersurface of the connector housing, and a locking portion defined on theouter surface of the connector housing and interrupting the nominalhousing portion of the connector housing, the locking portion of theconnector housing includes a port engagement face that extends inwardfrom the nominal housing portion of the connector housing toward thelongitudinal axis and is oriented transverse to the longitudinal axis,the locking portion of the connector housing further includes a lockingportion recess positioned rearward of the port engagement face of thelocking portion and inward of the nominal housing portion of theconnector housing, the locking portion recess is oriented transverse tothe port engagement face of the locking portion and includes a planarsurface extending across at least a portion of the outer surface of theconnector housing, the ferrule includes a 2.5 millimeter nominal ferrulediameter, is retained by the ferrule retaining portion of the connectorhousing, and includes an optical fiber bore, the cable adapter includesan optical cable passageway, an optical fiber passageway, a housinginsert portion seated in the adapter seating portion of the connectorhousing to align the optical cable passageway and the optical fiberpassageway with the longitudinal axis of the connector housing, and anadapter abutment limiting an extent to which the cable adapter extendsinto the adapter seating portion of the connector housing, the fiberoptic cable extends along the optical cable passageway of the cableadapter and includes an optical fiber extending along optical fiberpassageway of the cable adapter and the optical fiber bore of theferrule, the type SC conversion housing surrounds the ferrule retainingportion of the connector housing and a portion of the connector housingrearward of the ferrule retaining portion of the connector housing, andthe type SC conversion housing is positioned forward of the lockingportion of the connector housing along the longitudinal axis of theconnector housing such that the type SC conversion housing would presentpotential interfere with engagement of the locking portion of theconnector housing with a securing member of an optical port.

In yet another embodiment, a connectorized fiber optic cable assemblyincludes a ferrule, a connector housing, a cable adapter, a fiber opticcable, and a hardened conversion housing, where the connector housingincludes a ferrule retaining portion positioned at a front portion ofthe connector housing, an adapter seating portion, a longitudinal axisextending transversely from a leading edge plane of the front portion ofthe connector housing, through the ferrule retaining portion and theadapter seating portion of the connector housing, to a rear portion ofthe connector housing, a nominal housing portion defined on an outersurface of the connector housing, and a locking portion defined on theouter surface of the connector housing and interrupting the nominalhousing portion of the connector housing, the locking portion of theconnector housing includes a port engagement face that extends inwardfrom the nominal housing portion of the connector housing toward thelongitudinal axis and is oriented transverse to the longitudinal axis,the locking portion of the connector housing further includes a lockingportion recess positioned rearward of the port engagement face of thelocking portion and inward of the nominal housing portion of theconnector housing, the locking portion recess is oriented transverse tothe port engagement face of the locking portion and includes a planarsurface extending across at least a portion of the outer surface of theconnector housing, the ferrule includes a 2.5 millimeter nominal ferrulediameter, is retained by the ferrule retaining portion of the connectorhousing, and includes an optical fiber bore, the cable adapter includesan optical cable passageway, an optical fiber passageway, a housinginsert portion seated in the adapter seating portion of the connectorhousing to align the optical cable passageway and the optical fiberpassageway with the longitudinal axis of the connector housing, and anadapter abutment limiting an extent to which the cable adapter extendsinto the adapter seating portion of the connector housing, the fiberoptic cable extends along the optical cable passageway of the cableadapter and includes an optical fiber extending along optical fiberpassageway of the cable adapter and the optical fiber bore of theferrule, the hardened conversion housing includes a pair of opposingfingers includes opposing interior faces that extend parallel to, andare arranged symmetrically about, the longitudinal axis of the connectorhousing, a finger spacing between the opposing interior faces of theopposing fingers is between 10.80 millimeters and 10.85 millimeters, afinger depth along a direction parallel to the longitudinal axis of theconnector housing is between 8.45 millimeters and 8.55 millimeters, afinger width along a direction perpendicular to the finger depth and thelongitudinal axis of the connector housing is less than 10 millimeters,outer faces of the opposing fingers lie along a common outside diameterof between 15.75 millimeters and 15.85 millimeters, an outer face of oneof the opposing fingers is truncated in a plane parallel to the opposinginterior faces to define a truncated span e of between about 14.75millimeters and about 14.95 millimeters, extending from the outer faceof the truncated opposing finger to the outer face of the oppositefinger, and the hardened conversion housing surrounds the ferruleretaining portion of the connector housing and the locking portion ofthe connector housing to interfere with engagement of the lockingportion of the connector housing with a securing member of an opticalport.

In yet another embodiment, a multiport assembly includes a shelldefining a cavity positioned within the shell, a plurality of opticaladapters positioned within the cavity of the shell, the optical adaptersstructurally configured to receive, align, and optically coupledissimilar optical connectors, a plurality of optical connection portsincluding respective connection port passageways permitting externaloptical connectors to access the plurality of optical adapterspositioned within the cavity of the shell, the connection portpassageways including respective connector insertion paths, and aplurality of push-button securing members associated with respectiveones of the connection port passageways, where each push-button securingmember is biased in an engaged position, in which a locking portion ofthe push-button securing member is positioned within a correspondingconnector insertion path, and is selectively positionable into and outof a disengaged position, in which the locking portion of thepush-button securing member is positioned outside the correspondingconnector insertion path, and the locking portion of each push-buttonsecuring member is configured to permit forcible nondestructivedisengagement of an external optical connector from the locking portionof the push-button securing member upon application of a force on theexternal optical connector in a direction along an axis extending alongthe corresponding connector insertion path.

In yet another embodiment, a multiport assembly includes a shelldefining a cavity positioned within the shell, a plurality of opticaladapters positioned within the cavity of the shell, the optical adaptersstructurally configured to receive, align, and optically coupledissimilar optical connectors, a plurality of optical connection portsincluding respective connection port passageways permitting externaloptical connectors to access the plurality of optical adapterspositioned within the cavity of the shell, the connection portpassageways including respective connector insertion paths, and aplurality of push-button securing members associated with respectiveones of the connection port passageways, where each push-button securingmember includes a locking portion, where the push-button securing memberis repositionable between a disengaged position, in which the lockingportion is positioned outside a corresponding connector insertion path,and an engaged position, in which the locking portion is positionedwithin the corresponding connector insertion path.

In yet another embodiment, a method for selectively connecting a fiberoptic connector to a multiport assembly includes inserting a connectorhousing of a fiber optic connector into a connector port of a multiportassembly, engaging a push-button securing member of the multiportassembly with the connector housing, moving the push-button securingmember away from a connector insertion path defined by the multiportassembly, moving the connector housing through the push-button securingmember of the multiport assembly, and engaging a locking portion of thepush-button securing member with the connector housing to selectivelycouple the connector housing to the multiport assembly.

In yet another embodiment, a method for selectively disconnecting afiber optic connector from a multiport assembly includes disengaging alocking portion of a push-button securing member of a multiport assemblyfrom a connector housing of a fiber optic connector, moving thepush-button securing member away from a connector insertion path definedby the multiport assembly, and moving the connector housing through thepush-button securing member of the multiport assembly.

Although the concepts of the present disclosure are described hereinwith reference to a set of drawings that show a particular type of fiberoptic cable, and connector components of particular size and shape, itis contemplated that the concepts may be employed in any optical fiberconnectorization scheme including, for example, and without limitation,hardened OptiTap® and OptiTip® connectors, field-installable UniCam®connectors, single or multi-fiber cable assemblies with SC, FC, LC, ormulti-fiber connectors, etc.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

The following detailed description of specific embodiments of thepresent disclosure can be best understood when read in conjunction withthe following drawings, where like structure is indicated with likereference numerals and in which:

FIG. 1 schematically depicts a perspective view of a fiber opticconnector including a connector housing, according to one or moreembodiments shown and described herein;

FIG. 2 schematically depicts a lower perspective view of the fiber opticconnector of FIG. 1 including a locking portion, according to one ormore embodiments shown and described herein;

FIG. 3A schematically depicts a cross-section of the fiber opticconnector of FIG. 1 , according to one or more embodiments shown anddescribed herein;

FIG. 3B schematically depicts another cross-section of a port engagementface of the fiber optic connector of FIG. 1 , according to one or moreembodiments shown and described herein;

FIG. 4 schematically depicts a top perspective view of the connectorhousing of the fiber optic connector of FIG. 1 , according to one ormore embodiments shown and described herein;

FIG. 5 schematically depicts a perspective cross-section of theconnector housing of the fiber optic connector of FIG. 1 , according toone or more embodiments shown and described herein;

FIG. 6 schematically depicts another cross-section of the fiber opticconnector of FIG. 1 , according to one or more embodiments shown anddescribed herein;

FIG. 7 schematically depicts the fiber optic connector of FIG. 1 with aconversion housing installed to the connecter housing, according to oneor more embodiments shown and described herein;

FIG. 8 schematically depicts an exploded view of the fiber opticconnector of FIG. 1 including another conversion housing, according toone or more embodiments shown and described herein;

FIG. 9 schematically depicts a cross-section of the conversion housingof FIG. 8 and a retaining member, according to one or more embodimentsshown and described herein;

FIG. 10 schematically depicts a rear perspective view of the retainingmember of FIG. 9 , according to one or more embodiments shown anddescribed herein;

FIG. 11 schematically depicts a front perspective view of the retainingmember of FIG. 9 , according to one or more embodiments shown anddescribed herein;

FIG. 12 schematically depicts a perspective view of another connectorhousing, according to one or more embodiments shown and describedherein;

FIG. 13 schematically depicts a cross-section of the connector housingfor FIG. 12 along section 13-13 of FIG. 12 , according to one or moreembodiments shown and described herein;

FIG. 14 schematically depicts a perspective view of another connectorhousing, according to one or more embodiments shown and describedherein;

FIG. 15 schematically depicts a perspective view of another connectorhousing, according to one or more embodiments shown and describedherein;

FIG. 16A schematically depicts a multiport assembly, according to one ormore embodiments shown and described herein;

FIG. 16B schematically depicts a cross-section of the multiport assemblyof FIG. 16A, according to one or more embodiments shown and describedherein;

FIG. 17 schematically depicts cross-section of an optical connector portof the multiport assembly of FIG. 16 , according to one or moreembodiments shown and described herein;

FIG. 18 schematically depicts a fiber optic connector inserted into theoptical connector port of FIG. 17 , according to one or more embodimentsshown and described herein;

FIG. 19 schematically depicts a front perspective view of a push-buttonsecuring member of the multiport assembly of FIG. 16 , according to oneor more embodiments shown and described herein;

FIG. 20 schematically depicts a rear perspective view of a push-buttonsecuring member of the multiport assembly of FIG. 16 , according to oneor more embodiments shown and described herein;

FIG. 21 schematically depicts a side perspective view of a push-buttonsecuring member of the multiport assembly of FIG. 16 , according to oneor more embodiments shown and described herein;

FIG. 22 schematically depicts a fiber optic connector approaching themultiport assembly of FIG. 16 , according to one or more embodimentsshown and described herein;

FIG. 23 schematically depicts the fiber optic connector inserted withinan optical connection port of the multiport assembly of FIG. 16 ,according to one or more embodiments shown and described herein;

FIG. 24 schematically depicts the fiber optic connector further insertedwithin the optical connection port of the multiport assembly of FIG. 16, according to one or more embodiments shown and described herein;

FIG. 25 schematically depicts a side cross-section view of the fiberoptic connector inserted within the optical connection port of themultiport assembly of FIG. 16 , according to one or more embodimentsshown and described herein;

FIG. 26 schematically depicts the fiber optic connector engaging apush-button securing member of the multiport assembly of FIG. 16 ,according to one or more embodiments shown and described herein;

FIG. 27 schematically depicts the fiber optic connector fully insertedto the optical connection port of the multiport assembly of FIG. 16 ,according to one or more embodiments shown and described herein;

FIG. 28 schematically depicts a front view of another push-buttonsecuring member according to one or more embodiments shown and describedherein;

FIG. 29 schematically depicts a top view of a push-button of thepush-button securing member of FIG. 28 , according to one or moreembodiments shown and described herein;

FIG. 30 schematically depicts another top view of the push-button of thepush-button securing member of FIG. 28 with an o-ring seated to thepush-button, according to one or more embodiments shown and describedherein;

FIG. 31 schematically depicts a bottom view of the push-button of FIG.29 , according to one or more embodiments shown and described herein;

FIG. 32 schematically depicts a blank for making the push-buttonsecuring member of FIG. 28 , according to one or more embodiments shownand described herein;

FIG. 33 schematically depicts the push-button securing member of FIG. 28in isolation, according to one or more embodiments shown and describedherein;

FIG. 34 schematically depicts another multiport assembly including apush-button securing member, according to one or more embodiments shownand described herein;

FIG. 35 schematically depicts a cross section of the multiport assemblyand push-button securing member of FIG. 34 , according to one or moreembodiments shown and described herein; and

FIG. 36 schematically depicts the push-button securing member of FIG. 34in isolation, according to one or more embodiments shown and describedherein.

DETAILED DESCRIPTION

Embodiments described herein generally relate to various devices forforming an optical connection between optical fibers. More particularly,embodiments described herein include fiber optic connectors includingconnector housings having a locking portion that selectively engages apush-button securing member of a multiport assembly to selectivelycouple the fiber optic connector to the multiport assembly. The lockingportion of the connector housing and/or the push-button securing memberof the multiport assembly may be configured to allow forcible,non-destructive disengagement of the connector housing from themultiport assembly upon the application of a predetermined force to theconnector housing. In this way, damage to the multiport assembly and/orthe fiber optic connector resulting from unexpected or unintended forcesapplied to the connector housing may be minimized.

In embodiments, the push-button securing members may generally intersecta connection port passageway of the multiport assembly, which may reducethe need for securing features positioned on the perimeter of theconnection port passageway. By reducing the need for securing featurespositioned on the perimeter of the connection port passageway, adjacentconnection port passageways on the multiport assembly may be positionedcloser to one another such that a greater number of connection portpassageways to be included in a multiport assembly without increasingthe overall size of the multiport assembly. Furthermore, the push-buttonsecuring members may be configured to automatically engage a connectorhousing upon the full insertion of the connector housing to theconnection port passageway, such that a user may selectively couple theconnector housing to the multiport assembly with one hand, therebysimplifying the connection of the connector housing to the multiportassembly. The connector housings may further include a keying portionthat selectively engages a corresponding keying portion of the multiportassembly to ensure and maintain the rotational orientation of the fiberoptic connector with the multiport assembly. These and other embodimentsof fiber optic connectors and multiport assemblies are disclosed ingreater detail herein with reference to the appended figures.

As used herein, the term “advancing direction” refers to a directionthat is parallel to a longitudinal axis of the connector housing and inwhich the connector housing may be inserted into a corresponding port.Conversely, reference herein to the “retracting direction” refers to theopposite direction, i.e., a direction that is parallel to thelongitudinal axis of the connector housing and in which the connectorhousing may be retracted from a corresponding port. In the appendedfigures, the advancing direction is depicted as “AD” and the retractingdirection is depicted as “RD.”

Referring initially to FIG. 1 , a perspective view of a fiber opticconnector 100 is schematically depicted. The fiber optic connector 100generally includes a connector housing 110, including a ferruleretaining portion 112 at a front portion 111 of the connector housing110. The connector housing 110 further includes a rear portion 113positioned opposite the front portion 111 in an axial direction. Theferrule retaining portion 112 of the connector housing 110 is generallyconfigured to hold and retain a ferrule 102 that is positioned at leastpartially within the ferrule retaining portion 112.

In embodiments, the fiber optic connector 100 is coupled to a fiberoptic cable 10 at the rear portion 113 of the fiber optic connector 100.The fiber optic cable 10 generally includes an optical fiber 12extending through the fiber optic cable 10. The optical fiber 12 maygenerally extend through the connector housing 110 and the ferrule 102along a longitudinal axis 114 of the connector housing 110. For fiberoptic cables 10 including a single optical fiber 12, the optical fiber12 may be coaxial with the longitudinal axis 114. For multifiber cables,this alignment will be orthogonally offset for one, more than one, orall of the optical fibers of the cable.

In embodiments, the connector housing 110 generally includes an outersurface 118 that extends around a perimeter of the connector housing110, and the outer surface 118 may include one or more cross-sectionalshapes. For example, in the embodiment depicted in FIG. 1 , the frontportion 111 of the connector housing 110 includes a rectangularcross-section including planar sides, while the rear portion 113 of theconnector housing 110 includes a curved outer surface 118.

Referring to FIG. 2 , a lower perspective view of the connector housing110 is schematically depicted. The connector housing 110 includes anominal housing portion 120 defined on the outer surface 118 of theconnector housing 110. The nominal housing portion 120 extends about andaxially along the outer surface 118 of the connector housing 110 but maybe interrupted by a variety of distinctive surface features defined onthe outer surface 118 of the connector housing 110. The nominal housingportion 120 is referenced herein as being “nominal” to help distinguishit from the various distinctive surface features that are defined on theconnector housing 110. Without these distinctive surface features, thenominal housing portion 120 would form a relatively uniform andcontinuous surface of the connector housing 110, and would extend farenough along a length of the connector housing 110 to provide aconvenient surface for a user to handle the connector housing 110without the use of a specialized connector handling tool or othersupplemental hardware. Reference herein to a surface feature, e.g., akeying portion or a locking portion, that is “defined on” the outersurface 118 of the connector housing 110 contemplates that the surfacefeature may be a subtractive surface feature, like a cut-out, or anadditive surface feature, like a projection.

In the embodiment depicted in FIG. 2 , the connector housing 110includes a locking portion 130 defined on the outer surface 118 at therear portion 113 of the connector housing 110. The locking portion 130is positioned on a curved surface of the outer surface 118 in theembodiment depicted in FIG. 2 , and generally includes a port engagementface 132 that extends inward from the nominal housing portion 120 towardthe longitudinal axis 114 of the connector housing 110. In oneembodiment, the port engagement face 132 may generally define anedge-to-edge cross sectional cut-out of the connector housing 110, inwhich the port engagement face 132 extends across the outer surface 118in a direction transverse to the longitudinal axis 114. In otherembodiments, the port engagement face 132 may generally define a pocketcut-out of the connector housing 110, in which the port engagement face132 extends radially inward from the outer surface 118 toward thelongitudinal axis 114, and is bounded in a circumferential direction bythe nominal housing portion 120.

The locking portion 130 further includes a locking portion recess 134positioned rearward of the port engagement face 132 and inward of thenominal housing portion 120. The locking portion recess 134 includes agenerally planar surface 136 that is oriented transverse to the portengagement face 132 and that extends at least partially across the outersurface 118 of the connector housing 110. The locking portion recess 134may also include a ramp portion 138 positioned rearward of the planarsurface 136 and that extends outward from the planar surface 136 to thenominal housing portion 120 moving along the locking portion recess 134in the retracting direction.

In embodiments, the port engagement face 132 extends inward from thenominal housing portion 120 of the connector housing 110 by a distancethat corresponds to features of a push-button securing member 230 (FIG.17 ) such that the connector housing 110 may be selectively coupled toand removed from the push-button securing member 230 (FIG. 17 ). In oneembodiment, the port engagement face 132 extends inward from the nominalhousing portion 120 by a distance of at least about 0.75 millimeters.

Referring collectively to FIGS. 2 and 3A, the port engagement face 132generally defines a planar surface that is oriented transverse to thelongitudinal axis 114. The port engagement face 132 includes and extendsbetween an inner end 131 and an outer end 133 that is positioned outwardof the inner end 131. The outer end 133 may include a rounded orchamfered edge, which may assist in preventing breakage of the outer end133 when the connector housing 110 is forcibly removed from a connectionport, as described in greater detail herein.

In some embodiments, the outer end 133 is positioned closer to the frontportion 111 of the connector housing 110 in an axial direction than theinner end 131, such that the port engagement face 132 is both rearwardand outward facing. In these embodiments, the port engagement face 132generally defines a plane that intersects the longitudinal axis 114 atan angle that is less than 30 degrees evaluated from perpendicular.

For example, as best shown in FIG. 5 , the port engagement face 132 is aformed as a rearward-facing cut-out that lies in a plane that intersectsthe longitudinal axis 114 at an acute angle α₁, and the ramp portion 138is formed as a forward-facing cut-out that lies in a plane thatintersects the longitudinal axis 114 at an angle α₂ that is greater thanα₁. In embodiments, α₂ is generally between 110 degrees and 180 degreesand may generally be selected to correspond to a feature of apush-button securing member 230 (FIG. 17 ), as described in greaterdetail herein. As noted above, in embodiments, the angle α₁ is generallywithin 30 degrees of perpendicular (i.e., the port engagement face 132lies in a plane that intersects the longitudinal axis at an anglebetween 60 degrees and 90 degrees) such that the port engagement face132 is outward and rearward facing. By orienting the port engagementface 132 in a rearward and outward facing orientation, the portengagement face 132 may be selectively disengaged from a push-buttonsecuring member 230 (FIG. 17 ) upon the application of a force above apredetermined threshold, as described in greater detail herein. In otherembodiments, the port engagement face 132 is oriented such that the portengagement face 132 that extends in a plane that is orthogonal to thelongitudinal axis 114.

Referring to FIG. 3B, in some embodiments, the port engagement face 132may include a locking face 135 that extends in a plane that isorthogonal to the longitudinal axis 114 (FIG. 3A), and a release face137 positioned outward from the locking face 135. In the embodimentdepicted in FIG. 3B, the release face 137 extends in a plane thatintersects the locking face 135 at an angle (pi. In embodiments, theangle (pi is between about 0 degrees and 30 degrees, inclusive of theendpoints, such that the release face 137 is outward and rearwardfacing. By including both a locking face 135 that extends in a planethat is orthogonal to the longitudinal axis 114 and a release face 137that is outward and rearward facing, the port engagement face 132 of theconnector housing 110 may be rigidly connected to a push-button securingmember 230 (FIG. 17 ) engaged with the locking face 135. However, theport engagement face 132 of the connector housing may be releasablyengaged with a push-button securing member 230 (FIG. 17 ) engaged withthe release face 137 upon the application of a force above apredetermined threshold, as described in greater detail herein.

Referring again to FIGS. 2 and 3A, in embodiments, the front portion 111has a perimeter extending around the outer surface 118 of the frontportion 111 that is less than a perimeter extending around the outersurface 118 of the rear portion 113 of the connector housing 110. Theconnector housing further includes a transition region 116 positionedbetween the front portion 111 and the rear portion 113, where theperimeter of the connector housing 110 extending around the outersurface 118 increases moving along the transition region 116 from thefront portion 111 to the rear portion 113 in an axial direction.

In embodiments, the connector housing 110 includes a thread 122extending around the outer surface 118 at the transition region 116. Thethread 122 generally includes crests 126 that are separated from oneanother by a pitch 124. The thread 122 may be utilized to selectivelycouple one or more conversion housings to the connector housing 110, asdescribed in greater detail herein. While the thread 122 is depicted asbeing positioned on the transition region 116, it should be understoodthat the thread 122 may be alternatively or additionally positioned onthe outer surface 118 of the front portion 111 and/or the rear portion113 of the connector housing 110.

In embodiments, the pitch 124 between the crests 126 of the thread 122is less than a length 140 of the locking portion recess 134 evaluated inan axial direction. Because the pitch 124 of the thread 122 is less thanthe length 140 of the locking portion recess 134, the locking portionrecess 134 may selectively interact with a push-button securing member230 (FIG. 17 ) while the pitch 124 prevents the thread 122 frominteracting the push-button securing member 230 (FIG. 17 ), as describedin greater detail herein.

Referring particularly to FIG. 3A, the ferrule 102 is positioned withinand engaged with the ferrule retaining portion 112 of the connectorhousing 110. The ferrule 102 defines an optical fiber bore 104 that isconfigured to retain the optical fiber 12. The optical fiber bore 104 isgenerally aligned with the longitudinal axis 114 of the connectorhousing 110 such that the longitudinal axis 114 is coaxial with theoptical fiber bore 104.

Referring collectively to FIGS. 4 and 5 , a perspective view of theconnector housing 110 and a cross-section of the fiber optic connector100 are schematically depicted. The connector housing 110 includes akeying portion 150 defined on the outer surface 118 of the connectorhousing 110, the keying portion 150 including pair of opposing contactsurfaces 152. The opposing contact surfaces 152 are structurallyconfigured to inhibit rotation of the connector housing 110 about thelongitudinal axis 114 when engaged with a complementary keying portionof an optical connection port 220 (FIG. 17 ). In the embodiment depictedin FIGS. 4 and 5 , the keying portion 150 is positioned at the rearportion 113 of the connector housing 110, and interrupts the nominalhousing portion 120. In embodiments, the keying portion 150 of theconnector housing 110 extends closer to the front portion 111 of theconnector housing 110 than does the locking portion 130 of the connectorhousing 110, such that the keying portion 150 may contact features of anoptical connection port 220 (FIG. 17 ) prior to the locking portion 130,as described in greater detail herein. In the embodiment depicted inFIG. 5 , the keying portion 150 of the connector housing 110 extends atleast partially into the transition region 116 of the connector housing110. In some embodiments, the keying portion 150 may only extend forwardinto the transition region 116, such that the keying portion 150terminates prior to the front portion 111 of the connector housing 110moving forward along the outer surface 118. The keying portion 150 maygenerally extend in an axial direction a distance that is longer thanthe transition region 116 and/or the front portion 111 in the axialdirection.

Referring to FIGS. 5 and 6 , in embodiments, the keying portion 150and/or the locking portion 130 (and portions thereof) may berotationally discrete on the outer surface 118 of the connector housing110. As used herein, the term “rotationally” discrete represents alimited width-wise extent along the outer surface 118 of the connectorhousing 110, as the connector housing 110 is rotated about itslongitudinal axis 114. For example, the keying portion 150 may berelatively long and have a relatively narrow width, which width can bedescribed with reference to the rotational arc θ₁ circumscribed by thewidth of the keying portion 150 relative to the longitudinal axis 114 ofthe connector housing 110. In the illustrated embodiments, the arc θ₁ isabout 50 degrees, and it is contemplated that the arc θ₁ may, in manyembodiments, be between about 30 degrees and about 70 degrees.Similarly, in the illustrated embodiments, the locking portion 130 iswider than the keying portion 150, i.e., about 90 degrees, and it iscontemplated that the arc θ₂ circumscribed by the width of the lockingportion 130 may be between about 120 degrees and about 60 degrees. Insome embodiments, the locking portion 130 is wider than the keyingportion 150 such that the rotational arc θ₁ is less than about 30% ofthe rotational arc θ₂. In one embodiment, the rotational arc θ₂ is lessthan 90 degrees. In the embodiment depicted in FIGS. 5 and 6 therotational arcs θ₁, θ₂ are mutually exclusive such that the keyingportion 150 and the locking portion 130 are defined on different surfaceportions of the outer surface of the connector housing. In oneembodiment, the rotational arc θ₂ circumscribed by the width of thelocking portion 130 relative to the longitudinal axis 114 of theconnector housing 110 is greater than about 90 degrees, and therotational arc θ₁ circumscribed by the width of the keying portion 150relative to the longitudinal axis 114 of the housing is less than arotational arc θ₂. In another embodiment, the rotational arc θ₂circumscribed by the width of the locking portion 130 relative to thelongitudinal axis 114 of the connector housing 110 is less than about120 degrees, and the rotational arc θ₁ is greater than about 60 degrees,but does not exceed about 70 degrees. In one embodiment, the sum of therotational arcs θ₁, θ₂ are limited such that (θ₁+θ₂)<180°.

The keying portion 150 generally has an unobstructed line of sight to aleading edge plane 115 that is defined by the front portion 111 of theconnector housing 110 and that is orthogonal to the longitudinal axis114. The keying portion 150 of the connector housing 110 helps to ensureproper rotational orientation of the fiber optic connector 100 when itis engaged with an optical connection port 220 (FIG. 17 ) having acomplementary keying portion. The locking portion 130 can also beconfigured to help ensure that the connector housing 110 cannot beinadvertently locked into an optical connection port 220 (FIG. 17 ) in arotationally misaligned state. It is contemplated that it may beinsufficient to rely on the locking portion 130 alone for properrotational alignment of the connector housing because, in someinstances, there will not be close contact between the respectivesurfaces of the locking portion recess 134 and a push-button securingmember 230 (FIG. 17 ) of an optical connection port 220 (FIG. 17 ). Infact, in some embodiments a gap will be intentionally provided betweenthese surfaces to isolate a spring-loaded movement of the push-buttonsecuring member 230 (FIG. 17 ) of the optical connection port 220 (FIG.17 ) from the connector housing 110, as described in greater detailherein. It is also noteworthy that the locking portion 130 does notenjoy an unobstructed line of sight with the leading edge plane 115 ofthe connector housing 110, as is the case with the keying portion 150.The unobstructed line of sight of the keying portion 150 can be used tohelp ensure proper rotational orientation of the connector housing 110as the connector housing 110 is initially advanced into a complementaryoptical connection port 220 (FIG. 17 ), and before the obstructions ofthe locking portion 130 begin to interface and interfere with variousportions of the optical connection port 220 (FIG. 17 ). Accordingly,although in embodiments the keying portion 150 and the locking portion130 are both rotationally discrete and could conceivably be used ontheir own to help ensure proper rotational alignment, the presentinventors have recognized that it may be best to rely on the keyingportion 150 for rotational alignment, and the locking portion 130 forengagement, because the keying portion 150 enjoys an unobstructed lineof sight that is not subject to inadvertent interference with theoptical connection port 220 (FIG. 17 ), and the locking portion 130 isoften designed to avoid close contact with the hardware of the opticalconnection port 220 (FIG. 17 ).

In the embodiment depicted in FIGS. 5 and 6 , the keying portion 150comprises the pair of rotationally discrete contact surfaces 152 thatinterrupt the nominal housing portion 120 as a negative cut-out. Thediscrete contact surfaces 152 generally include planar surfaces that areaccessible without obstruction from the leading edge plane 115 of theconnector housing 110. The contact surfaces 152 generally line in planesthat intersect a plane defined by the port engagement face 132. In oneembodiment, the contact surfaces 152 lie in planes that are orthogonalto the port engagement face 132. For example, in the embodiment depictedin FIGS. 4 and 5 , the contact surfaces 152 lie in planes that aregenerally parallel with the longitudinal axis 114, such that the contactsurfaces 152 are may restrict rotation of the connector housing 110about the longitudinal axis 114. The port engagement face 132 generallylies in a plane that intersects the longitudinal axis 114 of theconnector housing 110, such that the port engagement face 132 mayrestrict axial movement of the connector housing 110 along thelongitudinal axis 114, such as when engaged with a corresponding surfacewithin an optical connection port 220 (FIG. 17 ).

Referring to FIG. 7 , a type SC conversion housing 180 is selectivelycoupled to the front portion 111 of the connector housing 110. In theembodiment depicted in FIG. 7 , the type SC conversion housing 180generally increases perimeter evaluated around the front portion 111 ofthe connector housing 110, to provide the connector housing 110 afootprint suitable for use in an SC type connection. Type SC conversionhousings are characterized by a connector footprint as set forth in IEC61754-4, published by the International Electrical Commission, whichdefines the standard interface dimensions for the type SC family offiber optic connectors and may be updated periodically. As is noted inthe aforementioned standard, the parent connector for the type SCconnector family is a single position plug connector which ischaracterized by a 2.5 millimeter nominal ferrule diameter. It includesa push-pull coupling mechanism which is spring loaded relative to theferrule in the direction of the optical axis. The plug has a single malekey which may be used to orient and limit the relative position betweenthe connector and the component to which it is mated. The opticalalignment mechanism of the connector is of a resilient sleeve style. IEC61754-4 defines the standard interface dimensions of active devicereceptacles for the type SC connectors. The receptacles are used toretain the connector plug and mechanically maintain the optical datumtarget of the plugs at a defined position within the receptaclehousings. The SC connector standard encompasses simplex plug connectorinterfaces, simplex adaptor connector interfaces, duplex plug connectorinterfaces, and duplex adaptor connector interfaces.

The connector housing 110 comprises a line of sight from the keyingportion 150 (FIG. 6 ) to the leading edge plane 115 (FIG. 5 ) of theconnector housing 110 that is obstructed only by the type SC conversionhousing 180 along the advancing direction of the fiber optic connector100. The type SC conversion housing 180 surrounds the ferrule retainingportion 112 (FIG. 4 ) of the connector housing 110 and a portion of theconnector housing 110 rearward of the ferrule retaining portion 112 ofthe connector housing 110. The type SC conversion housing 180 ispositioned forward of the locking portion 130 (FIG. 5 ) of the connectorhousing 110 along the longitudinal axis 114 of the connector housing 110such that the type SC conversion housing 180 would present potentialinterference with engagement of the locking portion 130 (FIG. 5 ) of theconnector housing 110 with a securing member of an optical port.

Referring to FIGS. 8, 9, 10, and 11 , a hardened conversion housing 182is schematically depicted. In embodiments, the hardened conversionhousing 182 includes internal threads that engage the thread 122 of theconnector housing 110. The hardened conversion housing 182 may beretained in place by a retention member 185 that may be selectivelycoupled to the front portion 111 of the connector housing 110. Theretention member 185 may be configured to mechanically interfere withand prevent rotation of the hardened conversion housing 182 with respectto the connector housing 110, thereby retaining the hardened conversionhousing 182 on the thread 122 of the connector housing 110. Inembodiments, the hardened conversion housing 182 includes opposingfingers 183 that comprise interior faces 187 that extend parallel to andare arranged symmetrically about the longitudinal axis 114 of theconnector housing 110. In embodiments, the opposing interior faces 187of the opposing fingers 183 are spaced apart from one another by adistance 189, which is selected to be between about 10.80 millimetersand about 10.85 millimeters, inclusive of the endpoints. Each of thefingers 183 have a depth 186 evaluated along a direction parallel to thelongitudinal axis 114 of the connector housing 110 that is between about8.45 millimeters and about 8.55 millimeters, inclusive of the endpoints.Each of the fingers 183 further include a width 188 evaluated along adirection perpendicular to the finger depth 186 and the longitudinalaxis 114 of the connector housing 110 that is less than about 10millimeters. Outer faces of the opposing fingers 183 lie along a commonoutside diameter 190 of between about 15.75 millimeters and about 15.85millimeters, inclusive of the endpoints. The outer face of one of theopposing fingers 183 is truncated in a plane parallel to the opposinginterior faces 187 to define a truncated span 192 extending from theouter face of the truncated opposing finger 183 to the outer face of theopposite finger 183, the span 192 being between about 14.75 millimetersand about 14.95 millimeters, inclusive of the endpoints.

In embodiments, the connector housing 110 comprises a line of sight fromthe keying portion 150 (FIG. 6 ) to the leading edge plane 115 (FIG. 5 )of the connector housing 110 that is obstructed only by the hardenedconversion housing 182 along the advancing direction of the fiber opticconnector 100. The hardened conversion housing 182 surrounds the ferruleretaining portion 112 (FIG. 4 ) of the connector housing 110 and aportion of the locking portion 130 (FIG. 5 ) of the connector housing110 such that the hardened conversion housing 182 would interfere withengagement of the locking portion 130 of the connector housing 110 witha securing member of an optical port.

Referring to FIGS. 12 and 13 , a perspective view and a cross-section ofanother embodiment of a connector housing 110 are schematicallydepicted, respectively. In the embodiment depicted in FIG. 13 , theouter surface 118 of the rear portion 113 of the connector housing 110includes planar surfaces, as compared to the curved surface depicted inFIG. 1 and described above. The planar surfaces may correspond to planarsurfaces within a port assembly configured to receive the connectorhousing. In the embodiment depicted in FIG. 13 , the outer surface 118of the rear portion 113 of the connector housing 110 forms a hexagonalshape, however, it should be understood that the connector housing 110may include any suitable number of planar surfaces. In the embodimentshown in FIGS. 12 and 13 , the connector housing 110 includes thelocking portion 130, but the keying portion 150 (FIG. 6 ) may optionallybe omitted. Because the connector housing 110 includes planar surfaceswhich may correspond to complementary planar surfaces in a portassembly, rotational mis-alignment between the connector housing 110 andthe port assembly may be limited. For example, the connector housing 110may only be insertable to the port assembly in a number of rotationalpositions that corresponds the number of planar surfaces of theconnector housing 110.

Referring to FIG. 14 , a perspective view of another connector housing110 is schematically depicted. In the embodiment depicted in FIG. 14 ,the thread 122 is positioned on the front portion 111 of the connectorhousing 110, forward of the transition region 116. As described above,the thread 122 may be utilized to selectively couple a conversionhousing to the connector housing, and the thread 122 may be positionedon the front portion 111, the transition region 116, and/or the rearportion 113 of the connector housing 110.

Referring to FIG. 15 , a perspective view of another connector housing110 is schematically depicted. In the embodiment depicted in FIG. 15 ,the contact surfaces 152 of the keying portion 150 extend outward as apositive surface projection from the connector housing 110, as comparedto the recessed contact surfaces 152 described above. The contactsurfaces 152 may be configured to engage with recessed contact surfacesof a port assembly to align the connector housing 110. Additionally, inthe embodiment depicted in FIG. 15 , the locking portion 130 is formedas a curved, concave surface recessed from the nominal housing portion120, as compared to the locking portions 130 described above having theport engagement face 132 (FIG. 5 ). The concave surface of the lockingportion 130 may be configured to engage with a push-button securingmember 230 (FIG. 28 ) including opposing arms 274 (FIG. 28 ), asdescribed in greater detail herein.

The fiber optic connectors 100 described above may be utilized tooptically couple the optical fibers 12 (FIG. 3A) to other opticalfibers. For example the fiber optic connectors 100 may be selectivelycoupled to an optical connector port to optically couple the opticalfiber 12 (FIG. 3A) to another optical fiber positioned within theoptical connector port. To facilitate the connection of multiple fiberoptic connectors 100, “multiport” assemblies described herein mayinclude multiple optical connector ports. The structure andconfiguration of example multiport assemblies and the interaction of theconnector housing 110 of the fiber optic connectors 100 are describedbelow.

Referring collectively to FIGS. 16A and 16B, a perspective view of amultiport assembly 200 and a section view of the multiport assembly 200along section 16B-16B are schematically depicted, respectively. Themultiport assembly 200 generally includes a plurality of opticalconnection ports 220 that are configured to receive fiber opticconnectors 100 (FIG. 1 ). In the embodiment depicted in FIG. 16A, themultiport assembly 200 includes five optical connection ports 220,however, it should be understood that multiport assemblies 200 accordingto the present disclosure may include any suitable number of opticalconnection ports 220. The multiport assembly 200 includes anupward-facing top surface 207 and an outward-facing front end 206. Inembodiments, the multiport assembly 200 generally includes scallops 205associated and aligned with each of the optical connection ports 220 andextending between the outward-facing front end 206 and the top surface207. The scallops 205 generally include a cut-out extending into theoutward-facing front end 206 and the top surface 207 of the multiportassembly 200 and may provide a tactile indication of the positioning ofthe optical connection ports 220 and a push-button securing member 230associated with the optical connection port 220. For example, a user mayinsert a fiber optic connector 100 (FIG. 1 ) into the optical connectionport 220, and/or may depress a push-button securing member 230 to removea fiber optic connector 100 (FIG. 1 ) from the multiport assembly 200.In some settings, the multiport assembly 220 may be difficult to reachand/or the user may not have a direct line of sight to the opticalconnection port 220 and/or the push-button securing member 230, and thescallop 205 may provide tactile feedback to the user to locate theoptical connection port 220 and/or the push-button securing member 230.

Referring collectively to FIGS. 17 and 18 , a cross-section of one ofthe plurality of optical connection ports 220 without and with a fiberoptic connector 100 positioned within the optical connection port 220are schematically depicted, respectively. In embodiments the opticalconnection ports 220 are generally positioned at a front end 206 of themultiport assembly 200 and extend toward a rear end 208 of the multiportassembly 200 positioned opposite the front end 206. The multiportassembly 200 includes a shell 202 that defines a cavity 204 positionedwithin the shell 202. In the embodiment depicted in FIGS. 17 and 18 ,the shell 202 includes an upper member 201 that is coupled to a lowermember 203 to form the shell 202. In other embodiments, the shell 202may have a unitary construction, or may include multiple members coupledto one another to define the cavity 204.

In embodiments, the multiport assembly 200 includes a plurality ofoptical adapters 210 positioned in the cavity 204 that correspond toeach of the optical connection ports 220. Each of the optical adapters210 are structurally configured to receive, align, and optically coupledissimilar optical connectors. For example, the optical adapters 210 areconfigured to receive the fiber optic connector 100 on one side, andoptically couple the fiber optic connector 100 to another fiber opticconnector including a different shape.

Each of the optical connection ports 220 include a connection portpassageway 222 that includes an open end positioned opposite the cavity204 and that permits an external optical connector 100 to access acorresponding optical adapter 210 positioned within the cavity 204 ofthe shell 202. Each of the connection port passageways 222 define aconnector insertion path 224 extending inward along the connection portpassageway 222 to the optical adapter 210. The connector insertion path224 generally defines the path a fiber optic connector 100 follows uponbeing inserted to the connection port passageway 222.

The multiport assembly 200 includes a plurality of push-button securingmembers 230, each of which intersect a corresponding connector insertionpath 224. The push-button securing members 230 are movable in adirection that is transverse to the connection port passageway 222, asdescribed in further detail herein.

Referring collectively to FIGS. 19, 20, and 21 , a rear perspectiveview, a front perspective view, and a side view of a push-buttonsecuring member 230 are schematically depicted, respectively. Thepush-button securing members 230 generally include a main body 242 and aretention portion 240 extending outward from the main body 242. Theretention portion 240 may be configured to contact the shell 202 (FIG.18 ) of the multiport assembly 200 (FIG. 18 ) and retain the push-buttonsecuring members 230 within the shell 202 of the multiport assembly 200.Each push-button securing member 230 generally defines a bore 232extending through the push-button securing member 230, each bore 232defining an inner perimeter 231. While the bore 232 depicted in FIGS.19-21 is depicted as including a circular shape, it should be understoodthat the bore 232 may include any suitable shape for receiving a fiberoptic connector 100 (FIG. 1 ). For example, in some embodiments, thebore 232 may include planar surfaces configured to interface with planarsurfaces of a connector housing 110 (FIG. 13 ).

Each push-button securing member 230 includes a locking portion 233including a connector engagement face 234 positioned on the bore 232.When installed to the multiport assembly 200 (FIG. 17 ), in someembodiments, the connector engagement face 234 is generally orientedtransverse to the corresponding connector insertion path 224 (FIG. 17 ),and defines a locking portion recess 239 that is generally obstructedfrom the open end of the connector insertion path 224 (FIG. 17 ) by theconnector engagement face 234. The connector engagement face 234 extendsbetween an inner end 237 an outer end 235 positioned outward from theinner end 237, as evaluated from a center of the bore 232. Inembodiments, the outer end 235 may include a rounded or chamfered edge,which may assist in preventing breakage of the outer end 235 when aconnector housing 110 (FIG. 18 ) is forcibly removed from the connectionport passageway 222 (FIG. 18 ), as described in greater detail herein.

In some embodiments, the outer end 235 is positioned on the innerperimeter 231 of the bore 232 such that the connector engagement face234 extends inward from the inner perimeter 231. In other embodiments,the connector engagement face 234 may extend outward from the innerperimeter 231 of the bore 232. The push-button securing member 230further includes a ramp 236 that extends between the inner perimeter 231of the bore 232 to the inner end 237 of the connector engagement face234, such that the ramp 236 is upward and forward facing when thepush-button securing member 230 is positioned within the multiportassembly 200 (FIG. 17 ). The ramp 236 generally includes an ascendingportion 238 a that extends inward from the inner perimeter 231 of thebore 232 and a plateau portion 238 b that extends between the ascendingportion 238 a and the inner end 237 of the connector engagement face234. The ascending portion 238 a of the ramp 236 is oriented toprogressively constrict the corresponding connector insertion path 224(FIG. 17 ).

Referring again to FIGS. 17 and 18 , the plateau portion 238 b of eachof the push-button securing members 230 is generally aligned with theconnector insertion path 224. In embodiments, the ramp 236 of each ofthe push-button securing members 230 is positioned forward of theconnector engagement face 234 of the push-button securing members 230.In other words, the ramps 236 of each of the push-button securingmembers 230 are positioned closer to the front end 206 of the multiportassembly 200 than the connector engagement face 234 of the push-buttonsecuring member 230. In this way, the ramp 236 may contact a fiber opticconnector 100 being inserted along the connector insertion path 224prior to the connector engagement face 234, as described in greaterdetail herein.

In some embodiments, the connector engagement face 234 of each of thepush-button securing members 230 defines a plane that is orthogonal tothe connector insertion path 224. In other embodiments, the connectorengagement face 234 of each of the push-button securing members 230 areoriented such that the inner end 237 (FIG. 20 ) of the connectorengagement face 234 is positioned closer to the front end 206 of themultiport assembly 200 than the outer end 235 (FIG. 20 ) of theconnector engagement face 234. In these embodiments, the connectorengagement face 234 of each of the plurality of push-button securingmembers 230 defines a plane that intersects the corresponding connectorinsertion path 224 at an angle that is less than 30 degrees fromperpendicular, such that the connector engagement face 234 facesrearward and upward. By orienting the connector engagement face 234 ofeach of the push-button securing members 230 rearward and upward, afiber optic connector 100 may be removed from the multiport assembly 200upon an application of force to the fiber optic connector 100 in adirection along the connector insertion path 224, as described ingreater detail herein.

In embodiments, a resilient member 250 is engaged with each of thepush-button securing members 230. The resilient members 250 may bias thepush-button securing members 230, and may generally include a spring,such as and without limitation a compression spring, a tension spring, atorsion spring, or the like. In embodiments, the resilient members 250include a spring constant of between about 10 newtons per millimeter andabout 50 newtons per millimeter, inclusive of the endpoints. In anotherembodiment, the resilient members 250 include a spring constant ofbetween about 12 newtons per millimeter and about 16 newtons permillimeter, inclusive of the endpoints. Increasing the spring constantmay increase a force required to move the push-button securing members230 between an engaged position and a disengaged position, as describedin greater detail herein. The resilient members 250 may include a freelength of between about 3 millimeters and about 20 millimeters,inclusive of the endpoints. In one embodiment, the resilient members 250have a free length of between about 5 millimeters and about 8millimeters, inclusive of the endpoints.

The push-button securing members 230 are repositionable between anengaged position, in which the locking portion 233 of each of thepush-button securing members 230 is positioned within and intersects thecorresponding connector insertion path 224, and a disengaged position,in which the locking portion 233 is spaced apart from the correspondingconnector insertion path 224. More particularly, the push-buttonsecuring members 230 are repositionable between an engaged position, inwhich the connector engagement face 234 of each of the push-buttonsecuring members 230 is positioned within and intersects thecorresponding connector insertion path 224, and a disengaged position,in which the connector engagement face 234 is spaced apart from thecorresponding connector insertion path 224.

In embodiments, the resilient members 250 bias the push-button securingmembers 230 into the engaged position, such that a force must be appliedto resilient members 250 to reposition the push-button securing members230 into the disengaged position.

For example and referring to FIG. 22 , a fiber optic connector 100 isdepicted approaching an optical connection port 220. As shown in FIG. 22, the front portion 111 of the connector housing 110 is initiallyinserted within the connector insertion path 224 of the connection portpassageway 222.

Referring to FIG. 23 , as the fiber optic connector 100 is furtherinserted along the connector insertion path 224, the front portion 111of the connector housing 110 may pass through the bore 232 of thepush-button securing member 230. As described above, in some embodimentsthe perimeter of the front portion 111 of the connector housing 110 maybe less than a perimeter of the rear portion 113 of the connectorhousing 110, and in some configurations, the front portion 111 of theconnector housing may be sized to pass through the bore 232 of thepush-button securing member 230 without contacting the ramp 236 of thepush-button securing member 230.

Referring collectively to FIGS. 24 and 25 , the optical connector port220 includes a rotationally discrete keying portion 260 extending inwardinto the connector insertion path 224. The rotationally discrete keyingportion 260 comprises includes rotationally discrete contact surfaces,more particularly a forward-facing surface 262 that is oriented to facethe open end of the connection port passageway 222, and one or morelateral-facing surfaces 264 that are configured to engage the contactsurfaces 152 of the keying portion 150 of the connector housing 110.Through engagement with the contact surfaces 152 of the keying portion150 of the connector housing 110, the lateral-facing surfaces 264 arestructurally configured to inhibit rotation of the connector housing 110when inserted into the connection port passageway 222. Each of therotationally discrete contact surfaces of the keying portion 260 of themultiport assembly 200 have an unobstructed line of sight with an openend of the connection port passageway 222.

As shown in FIGS. 24 and 25 , in some instances, the fiber opticconnector 100 may be inserted to the connection port passageway 222 withthe keying portion 150 of the connector housing 110 mis-aligned with thecorresponding keying portion 260 of the connection port passageway 222.In the embodiment depicted in FIGS. 24 and 25 , the keying portion 150of the connector housing 110 includes a recessed portion of theconnector housing and the keying portion 260 of the connection portpassageway 222 extends inward into the connector insertion path 224. Assuch the keying portion 260 may mechanically interfere with portions ofthe connector housing 110 other than the keying portion 150 of theconnector housing 110, preventing further insertion of the connectorhousing 110, as shown in FIGS. 24 and 25 . Instead, the connectorhousing 110 must be rotated to align the keying portion 150 of theconnector housing 110 with the keying portion 260 of the connection portpassageway 222 to allow further insertion of the connector housing 110into the connection port passageway 222. In some configurationsrotational alignment of the keying portion 150 of the connector housing110 with the keying portion 260 of the connection port passageway 222may assist in maintaining a suitable optical connection between theoptical fiber 12 (FIG. 3A) with an optical fiber positioned in theoptical adapter 210. For example and without being bound by theory, insome configurations, signal loss between the optical fiber 12 (FIG. 3A)and an optical fiber positioned in the optical adapter 210 may depend onthe rotational position of the optical fiber 12 (FIG. 3A) with respectto the optical fiber positioned in the optical adapter 210. As such, theoptical fiber 12 (FIG. 3A) may be positioned within the connectorhousing 110 such that the optical fiber 12 is rotationally aligned withthe optical fiber positioned in the optical adapter 210 when the keyingportion 150 is aligned with the keying portion 260 of the connectionport passageway 222.

As described above, in some embodiments, the keying portion 150 of theconnector housing 110 includes a positive surface projection (see e.g.,FIG. 14 ), as compared to the recessed keying portion 150 depicted inFIG. 25 . In these embodiments, the keying portion 260 of the connectionport passageway 222 may include a complementary recessed keying portion260 that similarly restricts insertion of the connector housing 110unless the keying portion 150 of the connector housing 110 isrotationally aligned with the keying portion 260 of the connection portpassageway 222.

Referring to FIG. 26 , with the keying portion 150 of the connectorhousing 110 aligned with the keying portion 260 of the connection portpassageway 222, the connector housing of the fiber optic connector 100may be further inserted into the connection port passageway 222. As theconnector housing 110 of the fiber optic connector 100 is furtherinserted, the connector housing 110 contacts the ramp 236 of thepush-button securing member 230. As described above, the ramp 236 isoriented to be upward and forward facing. As such, as the connectorhousing 110 is further inserted into the, axial force exerted on theramp 236 as the connector housing 110 is inserted may be resolved intodownward force applied to the push-button securing member 230. Thedownward force applied to the push-button securing member 230 moves thepush-button securing member 230 downward in a vertical direction that istransverse to the connector insertion path 224, and the locking portion233 including the connector engagement face 234 of the push-buttonsecuring member 230 may be moved out of the connector insertion path224, thereby moving the push-button securing member 230 into thedisengaged position. As described above, in embodiments, the resilientmember 250 is engaged with the push-button securing member 230 andbiases the push-button securing member 230 into the engaged position.Accordingly, in these embodiments, the biasing force of the resilientmember 250 must be overcome to move the push-button securing member 230into the disengaged position.

Referring to FIG. 27 , when the fiber optic connector 100 is fullyinserted to the connection port passageway 222, the front portion 111 ofthe connector housing 110 may be engaged with the optical adapter 210.Additionally, the push-button securing member 230 may be re-positionedback into the engaged position. More particularly, the port engagementface 132 (FIG. 26 ) of the connector housing 110 may be engaged with theconnector engagement face 234 of the push-button securing member 230,and the ramp 236 (FIG. 26 ) of the push-button securing member 230 maybe positioned within the locking portion recess 134 (FIG. 26 ) of theconnector housing 110. Engagement between the connector engagement face234 (FIG. 17 ) of the push-button securing member 230 (FIG. 17 ) withthe port engagement face 132 (FIG. 17 ) of the connector housing 110inhibits axial movement of the connector housing along the retractingdirection of the fiber optic connector 100 with respect to the multiportassembly 200, selectively coupling the connector housing 110 to themultiport assembly 200. Further, the retention portion 240 of thepush-button securing member 230 may strike and contact the shell 202 asthe push-button securing member 230 is repositioned to the engagedposition, which may produce an audible sound. A user inserting theconnector housing 110 may utilize the auditory sound of the retentionportion 240 hitting the shell 202 as confirmation that the connectorhousing 110 is fully inserted and is selectively coupled to themultiport assembly 200.

As best illustrated in the cross-section shown in FIG. 18 , a gap may bepositioned between the locking portion recess 134 of the connectorhousing and the ramp 236 of the push-button securing member 230, suchthat only the port engagement face 132 of the connector housing 110contacts the push-button securing member 230. In this way, minimalvertical forces may be transmitted from the push-button securing member230 to the connector housing 110, which may assist in maintainingalignment of the connector housing 110 with the optical adapter 210.

While in FIGS. 22-27 , a single optical connector port 220 is shown incross-section as described above, it should be understood that the otheroptical connector ports 220 of the multiport assembly 200 may besubstantially the same. With the fiber optic connector 100 inserted intothe optical connector port 220 and selectively coupled to thepush-button securing member 230, the optical fiber 12 (FIG. 1 ) of thefiber optic connector 100 may be optically coupled to another opticalfiber positioned within the optical adapter 210, forming a fiber opticjunction 300. By moving from the engaged position to the disengagedposition with the insertion of a fiber optic connector 100, and thenback to the engaged position upon the full insertion of the fiber opticconnector 100, a user may selectively couple the fiber optic connector100 to the multiport assembly 200 with one hand. In this way, themultiport assembly 200 and the connector housing 110 of the presentdisclosure may provide a significant benefit over conventional portassemblies which may require the use of two hands to manipulate abayonet connection, a locking nut connection, or the like.

Furthermore and referring to FIG. 27 , the use of push-button securingmembers 230 that are selectively positioned within a connector insertionpath 224 may allow a distance between adjacent optical connection ports220 to be reduced as compared to conventional port assemblies. Forexample, some conventional port assemblies utilize bayonet connectionsand/or locking nut connections, each of which require connectioncomponents positioned radially outward of a connector insertion path. Bycontrast, the push-button securing members 230 of the present disclosuregenerally intersect the connector insertion paths 224, minimizing theneed for connection components positioned outward of the connectorinsertion paths 224. As such, the distance between adjacent opticalconnection ports 220 may be reduced, allowing an increase in an overalldensity of optical connection ports 220 on the multiport assembly 200.For example, in the embodiment depicted in FIG. 27 , adjacent opticalconnection ports 220 may be spaced apart by a distance 280 evaluatedbetween central axes 282 extending along the connector insertion paths224 of the optical connection ports 220. In embodiments, the distance280 may be less than about 13 millimeters. Furthermore, while theembodiment depicted in FIG. 21 shows optical connection ports 220extending across the multiport assembly 200 in a lateral direction, itshould be understood that it is contemplated that multiport assemblies200 according to the present disclosure maybe positioned in any suitableorientation with respect to one another, and may be positioned on top ofone another in the vertical direction.

Referring again to FIG. 17 , to remove the fiber optic connector 100from the multiport assembly, the push-button securing member 230 ismoved from the engaged position back into a disengaged position bymoving the push-button securing member 230 downward in a direction thatis transverse to the central axis 282 extending along the connectorinsertion path 224 (e.g., in the vertical direction as depicted). Forexample, the push-button securing members 230 may be moved to thedisengaged position by depressing a top surface 228 of the push-buttonsecuring member 230 to overcome the biasing force of the resilientmember 250. In one embodiment, the push-button securing member may berepositioned into the disengaged position under a force exceeding apredetermined threshold between 5 newtons and 50 newtons applied to thepush-button securing member 230 in a direction that is transverse to theaxis extending along the corresponding connector insertion path 224. Inanother embodiment, the push-button securing member 230 may berepositioned into the disengaged position under a force exceeding apredetermined threshold between 20 newtons and 25 newtons applied to thepush-button securing member 230 in a direction that is transverse to theaxis extending along the corresponding connector insertion path 224.

In embodiments, each push-button securing member 230 is configured topermit forcible nondestructive disengagement of an external opticalconnector 100 from the locking portion 233 of the push-button securingmember 230 upon application of a force on the external optical connector100 in a direction along the central axis 282 extending along thecorresponding connector insertion path 224. For example, in embodiments,the push-button securing members 230 are configured to be repositionedinto the disengaged position upon the application of a force on theoptical connector 100, transmitted to the push-button securing member230 through the engagement between the connector engagement face 234 ofthe push-button securing member 230 and the port engagement face 132 ofthe connector housing 110. As described above, one or both of theconnector engagement face 234 of the push-button securing member 230 andthe port engagement face 132 of the connector housing 110 may beoriented at an angle with respect to the vertical direction as depicted(i.e., the port engagement face 132 of the connector housing at an anglefrom perpendicular with the longitudinal axis 114, and the connectorengagement face 234 at an angle from perpendicular with respect to theconnector insertion path 224). As such, a force applied to the connectorhousing 110 in an axial direction (i.e., along the connector insertionpath 224) may be resolved into a vertical force applied to thepush-button securing member 230 by the connector engagement face 234 ofthe push-button securing member 230 and/or the port engagement face 132of the connector housing 110. The vertical force may reposition thepush-button securing member 230 into the disengaged position.

Furthermore, as described above, the outer end 133 (FIG. 3 ) of the portengagement face 132 of the connector housing 110 and/or the outer end235 (FIG. 20 ) of the connector engagement face 234 of the push-buttonsecuring member 230 include chamfered or rounded edges. The chamferedand/or rounded edges of the outer end 133 (FIG. 3 ) of the portengagement face 132 of the connector housing 110 and/or the outer end235 (FIG. 20 ) of the connector engagement face 234 of the push-buttonsecuring member 230 may reduce point forces on the connector housing 110and/or the push-button securing member 230 as the push-button securingmember 230 is repositioned into the disengaged position. By reducingpoint forces on the connector housing 110 and/or the push-buttonsecuring member 230, breakage of the connector housing 110 and/or thepush-button securing member 230 may be reduced.

In one embodiment, the plurality of push-button securing members 230 areeach moved to the disengaged position upon the application upon theapplication of the force on the external optical connector 100 exceedinga predetermined threshold of between 20 newtons and 500 newtons,inclusive of the endpoints. In some embodiments, the plurality ofpush-button securing members 230 are each moved to the disengagedposition upon the application of the force on the external opticalconnector 100 exceeding a predetermined threshold of 20 newtons and 25newtons. As such, a fiber optic connector may be removed from themultiport assembly 200 upon the application of a predetermined force.This selective disengagement may assist in reducing damage to themultiport assembly 200 and/or the fiber optic connector 100, for examplein instances when unanticipated or undesired forces are applied to thefiber optic connector 100.

The force required to reposition the plurality of push-button securingmembers 230 into the disengaged position is related to the relativeorientation of the port engagement face 132 of the connector housing 110and the connector engagement face 234 of the push-button securing member230 and can be tailored as desired. For example, as described above, theport engagement face 132 is generally oriented to lie in a plane thatintersects the longitudinal axis 114 at an angle that is 30 degrees orless from perpendicular, and is oriented to be rearward and outwardfacing. Increasing the angle from perpendicular of the port engagementface 132 with respect to the longitudinal axis 114 (e.g., orienting theport engagement face 132 to be more downward facing) may reduce theforce required to remove the fiber optic connector 100, as more of theaxial force on the connector housing 110 may be resolved into thevertical direction. Conversely, as the angle of the port engagement face132 with respect to the longitudinal axis 114 approaches perpendicular,the force required to remove the fiber optic connector 100 willincrease, as less of the axial force on the connector housing 110 isresolved into the vertical direction.

Similarly, as described above, the connector engagement face 234 of eachof the push-button securing members 230 defines a plane that intersectsthe corresponding connector insertion path 224 at an angle that is lessthan 30 degrees from perpendicular, such that the connector engagementfaces 234 face rearward and upward. Increasing the angle fromperpendicular of the connector engagement face 234 with respect to theconnector insertion path 224 (e.g., orienting connector engagement face234 to be more upward facing) may reduce the force required to removethe fiber optic connector 100, as more of the axial force on theconnector housing 110 may be resolved into the vertical direction.Conversely, as the angle of the connector engagement face 234 withrespect to the connector insertion path 224 approaches perpendicular,the force required to remove the fiber optic connector 100 willincrease, as less of the axial force on the connector housing 110 isresolved into the vertical direction. In this way the orientation of theport engagement face 132 of the connector housing 110 and the connectorengagement face 234 of the push-button securing members 230 may betailored to achieve a desired force required to remove the connectorhousing 110 from the multiport assembly 200.

In some embodiments as described above, the port engagement face 132 mayinclude a locking face 135 (FIG. 3B) and a release face 137 (FIG. 3B).In these embodiments, the locking face 135 (FIG. 3B) may be configuredto engage a connector engagement face 234 of a push-button securingmember 230 that is oriented orthogonal to the connector insertion path224, thereby securing the connector housing 110 such that the connectorhousing 110 cannot be forcibly removed from the multiport assembly 200.In particular, as neither the connector engagement face 234 of thepush-button securing member 230 or the locking face 135 of the portengagement face 132 resolve axial force applied to the connector housinginto a vertical direction (i.e., as both the locking face 135 (FIG. 3B)and the connector engagement face 234 of the push-button securing member230 are oriented in the vertical direction), the connector housing 110may not be removed by axial force applied to the connector housing 110.In other configurations, the release face 137 (FIG. 3B) may beconfigured to engage a connector engagement face 234 of a push-buttonsecuring member 230, such that axial force applied to the connectorhousing 110 may resolve into a vertical force, and the connector housingmay be forcibly removed from the multiport assembly as described above.Accordingly, connector housings 110 including the port engagement face132 with both the locking face 135 (FIG. 3B) and the release face 137(FIG. 3B) may selectively be removable from multiport assemblies 200including push-button securing members 230 that engage the release face137 (FIG. 3B), while may be fixedly attached to multiport assemblies 200including push-button securing members 200 that engage the locking face135 (FIG. 3B).

Referring now to FIG. 28 , another embodiment of a push-button securingmember 230 is schematically depicted. In the embodiment depicted in FIG.28 , the push-button securing member 230 includes a push-button 270 anda securing member 272 including a pair of opposing arms 274 that areselectively deformable between the engaged position and the disengagedposition, in and out of the connector insertion path 224, respectively.In the embodiment depicted in FIG. 28 , the pair of opposing arms 274are elastically deformable in an outward direction from the connectorinsertion path 224 upon the depression of the push-button 270. In someconfigurations, the opposing arms 274 are configured to engage a concavelocking portion 130 (FIG. 15 ) of a connector housing 110.

Referring collectively to FIGS. 29-31 , top perspective views and abottom perspective view of the push-button 270 are schematicallydepicted respectively. In some embodiments, such as the embodimentsdepicted in FIGS. 29-31 , the push-button 270 includes a planar topsurface 271 and optionally includes an o-ring 269 that is seated on thepush-button 270. Referring particularly to FIG. 31 , in embodiments thepush-button 270 includes a wedge 273 positioned on a bottom surface thatis configured to engage and reposition the opposing arms 274 (FIG. 28 )into the disengaged position.

Referring to FIGS. 32 and 33 , a perspective view of a blank that may beused to form the securing member 272 and a perspective view of a formedsecuring member 272 are depicted, respectively. The securing member 272includes the opposing arms 274 that are configured to engage and retaina connector housing 110 (FIG. 27 ). The securing member 272 furtherincludes tabs 276 that are positioned on and extend outward from theopposing arms 274. Each of the tabs 276 include a flange 277 orientedtransverse to the connector insertion path 224 (FIG. 28 ). The flanges277 may be configured to engage the connector housing 110 (FIG. 27 ) andmove the opposing arms 274 outward as the connector housing 110 (FIG. 27) is inserted along the connector insertion path 224. The securingmember 272 further includes push-button flanges 278 positioned at a topend of the securing member 272. The push-button flanges 278 are orientedto face upward and are configured to engage the push-button 270, suchthat when the push-button 270 is depressed, the opposing arms 274 moveoutward to the disengaged position. In embodiments, the securing member272 may be selected such that the opposing arms 274 may selectivelydeform outward the application of the force on the external opticalconnector 100 exceeding a predetermined threshold between 20 newtons and25 newtons.

Referring to FIGS. 34-36 , another embodiment of the push-buttonsecuring member 230 is schematically depicted. Like the embodimentdescribed above with respect to FIGS. 28-33 , the push-button securingmember 230 includes a securing member 272 with selectively deformablearms 274, each having tabs 276 with flanges 277 that are orientedtransverse to the connector insertion path 224. However, in thisembodiment, the push-button flanges 278 are oriented to face outward andin the same direction as the flanges 277 on the opposing arms 274. Thisallows for the push-button 270 to be positioned in-line with theconnector insertion path 224, as depicted in FIG. 35 .

Accordingly, it should now be understood that embodiments describedherein include fiber optic connectors including connector housingshaving a locking portion that selectively engages a push-button securingmember of a multiport assembly to selectively couple the fiber opticconnector to the multiport assembly. The locking portion of theconnector housing and/or the push-button securing member of themultiport assembly may be configured to allow forcible, non-destructivedisengagement of the connector housing from the multiport assembly uponthe application of a predetermined force to the connector housing. Inthis way, damage to the multiport assembly and/or the fiber opticconnector resulting from unexpected or unintended forces applied to theconnector housing may be minimized.

In embodiments, the push-button securing members may generally intersecta connection port passageway of the multiport assembly, which may reducethe need for securing features positioned on the perimeter of theconnection port passageway. By reducing the need for securing featurespositioned on the perimeter of the connection port passageway, adjacentconnection port passageways on the multiport assembly may be positionedcloser to one another such that a greater number of connection portpassageways to be included in a multiport assembly without increasingthe overall size of the multiport assembly. Furthermore, the push-buttonsecuring members may be configured to automatically engage a connectorhousing upon the full insertion of the connector housing to theconnection port passageway, such that a user may selectively couple theconnector housing to the multiport assembly with one hand, therebysimplifying the connection of the connector housing to the multiportassembly. The connector housings may further include a keying portionthat selectively engages a corresponding keying portion of the multiportassembly to ensure and maintain the rotational orientation of the fiberoptic connector with the multiport assembly.

It is noted that recitations herein of a component of the presentdisclosure being “structurally configured” in a particular way, toembody a particular property, or to function in a particular manner, arestructural recitations, as opposed to recitations of intended use. Morespecifically, the references herein to the manner in which a componentis “structurally configured” denotes an existing physical condition ofthe component and, as such, is to be taken as a definite recitation ofthe structural characteristics of the component.

It is noted that terms like “preferably,” “commonly,” and “typically,”when utilized herein, are not utilized to limit the scope of the claimedinvention or to imply that certain features are critical, essential, oreven important to the structure or function of the claimed invention.Rather, these terms are merely intended to identify particular aspectsof an embodiment of the present disclosure or to emphasize alternativeor additional features that may or may not be utilized in a particularembodiment of the present disclosure.

For the purposes of describing and defining the present invention it isnoted that the terms “substantially” and “about” are utilized herein torepresent the inherent degree of uncertainty that may be attributed toany quantitative comparison, value, measurement, or otherrepresentation. The terms “substantially” and “about” are also utilizedherein to represent the degree by which a quantitative representationmay vary from a stated reference without resulting in a change in thebasic function of the subject matter at issue.

Having described the subject matter of the present disclosure in detailand by reference to specific embodiments thereof, it is noted that thevarious details disclosed herein should not be taken to imply that thesedetails relate to elements that are essential components of the variousembodiments described herein, even in cases where a particular elementis illustrated in each of the drawings that accompany the presentdescription. Further, it will be apparent that modifications andvariations are possible without departing from the scope of the presentdisclosure, including, but not limited to, embodiments defined in theappended claims. More specifically, although some aspects of the presentdisclosure are identified herein as preferred or particularlyadvantageous, it is contemplated that the present disclosure is notnecessarily limited to these aspects.

It is noted that one or more of the following claims utilize the term“wherein” as a transitional phrase. For the purposes of defining thepresent invention, it is noted that this term is introduced in theclaims as an open-ended transitional phrase that is used to introduce arecitation of a series of characteristics of the structure and should beinterpreted in like manner as the more commonly used open-ended preambleterm “comprising.”

We claim:
 1. A fiber optic connector, comprising: a ferrule comprisingan optical fiber bore; and a connector housing comprising: arotationally discrete keying portion defined on an outer surface of theconnector housing, wherein the rotationally discrete keying portioncomprises a recessed portion of the connector housing with anunobstructed line of sight from the rotationally discrete keying portionto a leading edge plane of the connector housing along an advancingdirection of the fiber optic connector; a front portion of the connectorhousing comprising a rectangular cross-section having planar sides, anda rear portion of the connector housing comprising a curved outersurface; and a rotationally discrete locking portion defined on theouter surface of the connector housing and interrupts the nominalhousing portion as a negative cut-out, the rotationally discrete lockingportion comprising a port engagement face, wherein the port engagementface is rearwardly facing.
 2. The fiber optic connector of claim 1,wherein the rotationally discrete locking portion comprises a lockingportion recess positioned rearward of the port engagement face.
 3. Thefiber optic connector of claim 2, wherein the locking portion recess isobstructed from the leading edge plane of the connector housing alongthe advancing direction of the fiber optic connector.
 4. The fiber opticconnector of claim 1, wherein the keying portion comprises a pair ofrotationally discrete contact surfaces that are accessible withoutobstruction from the leading edge plane of the connector housing.
 5. Thefiber optic connector of claim 4, wherein each of the rotationallydiscrete contact surfaces of the keying portion lie in planes thatextend orthogonally to a plane of the port engagement face.
 6. The fiberoptic connector of claim 4, wherein each of the rotationally discretecontact surfaces of the keying portion lie in planes that intersect theport engagement face.
 7. The fiber optic connector of claim 1, whereinthe port engagement face of the locking portion is formed from anedge-to-edge cross sectional cut-out of the connector housing.
 8. Thefiber optic connector of claim 7, wherein a rotational arc θ2circumscribed by the edge-to-edge cross sectional cut-out forming theport engagement face is less than 90 degrees.
 9. The fiber opticconnector of claim 1, wherein the keying portion of the connectorhousing extends closer to the front portion of the connector housingthan does the locking portion of the connector housing.
 10. The fiberoptic connector of claim 1, wherein: the keying portion comprises a pairof rotationally discrete contact surfaces that are accessible withoutobstruction from the leading edge plane of the connector housing; eachof the rotationally discrete contact surfaces of the keying portion liein planes that extend parallel to a longitudinal axis of the connectorhousing; and the port engagement face of the locking portion lies in aplane that is intersected by the longitudinal axis of the connectorhousing.
 11. The fiber optic connector of claim 1, wherein: the keyingportion and the locking portion circumscribe respective rotational arcsθ1, θ2 relative to a longitudinal axis of the connector housing; and therotational arcs θ1, θ2 Are mutually exclusive such that the keyingportion and the locking portion are defined on different surfaceportions of the outer surface of the connector housing.
 12. The fiberoptic connector of claim 1, wherein a rotational arc θ1 circumscribed bya width of the keying portion relative to a longitudinal axis of theconnector housing is less than a rotational arc θ2 circumscribed by thewidth of the locking portion relative to the longitudinal axis of theconnector housing.
 13. The fiber optic connector of claim 1, wherein:the connector housing further comprises a transition region between thefront portion of the connector housing and the locking portion of theconnector housing; and the keying portion of the connector housingextends at least partially into the transition region of the connectorhousing.
 14. The fiber optic connector of claim 13, wherein the keyingportion extends only partially into the transition region of theconnector housing.
 15. The fiber optic connector of claim 13, wherein alength of the keying portion exceeds a length of the transition regionalong a direction aligned with a longitudinal axis of the connectorhousing.
 16. The fiber optic connector of claim 13, wherein a length ofthe keying portion exceeds a length of the front portion of theconnector housing along a direction parallel to a longitudinal axis ofthe connector housing.
 17. The fiber optic connector of claim 1, whereinthe port engagement face of the locking portion, is formed from at leastone flat surface.
 18. The fiber optic connector of claim 1, wherein therotationally discrete locking portion is defined on the outer surface ofthe connector housing as a cut-out comprising: a rearward-facing cut-outsurface extending along a portion of a plane intersecting thelongitudinal axis of the connector housing at an acute angle α₁; and aforward facing cut-out surface intersecting the rearward-facing cut-outsurface and extending along a portion of a plane intersecting thelongitudinal axis of the connector housing at an angle α₂ that is largerthan the acute angle α₁.
 19. The fiber optic connector of claim 18,wherein α₂≤180° and α₁ is between 60° and 90°.
 20. The fiber opticconnector of claim 1, wherein the port engagement face defines a planethat intersects the longitudinal axis at an angle that is less than 30degrees from perpendicular.
 21. The fiber optic connector of claim 1,the locking portion recess comprises a planar surface that is orientedtransverse to the port engagement face and that extends at leastpartially across the outer surface of the connector housing.
 22. Thefiber optic connector of claim 1, wherein the rotationally discretekeying portion comprises a pair of rotationally discrete contactsurfaces that interrupt the nominal housing portion as a negativecut-out.
 23. A multiport assembly comprising: a shell defining a cavity;a plurality of optical adapters positioned within the cavity of theshell; a plurality of optical connector ports comprising respectiveconnection port passageways permitting external optical connectors toaccess the plurality of optical adapters positioned within the cavity ofthe shell, the connection port passageways comprising correspondingconnector insertion paths; and a plurality of push-button securingmembers associated with respective ones of the connection portpassageways, wherein each push-button securing member is biased in anengaged position, in which a rotationally discrete locking portion ofthe push-button securing member is positioned within the correspondingconnector insertion path, and is selectively positionable into and outof a disengaged position, in which the rotationally discrete lockingportion of the push-button securing member is positioned outside thecorresponding connector insertion path, the rotationally discretelocking portion of each push-button securing member comprises a ramporiented to progressively constrict the corresponding connectorinsertion path along an advancing direction of a fiber optic connectorin the respective connection port passageway.
 24. The multiport assemblyof claim 23, wherein the at least one rotationally discrete contactsurface of each keying portion is in unobstructed line of sight with theopen end of a respective connection port passageway and the at least onerotationally discrete contact surface is structurally configured toinhibit rotation of a connector housing residing in the respectiveconnection port passageway.
 25. The multiport assembly of claim 23,wherein the rotationally discrete locking portion of each push-buttonsecuring member comprises a connector engagement face structurallyconfigured to inhibit axial movement of a fiber optic connector in theconnection port passageway along a retracting direction of the fiberoptic connector in the respective connection port passageway.
 26. Themultiport assembly of claim 23, wherein the rotationally discretelocking portion of each push-button securing member comprises aconnector engagement face defines a plane that is orthogonal to itscorresponding connector insertion path.
 27. The multiport assembly ofclaim 23, further comprising a plurality of rotationally discrete keyingportions associated with respective ones of the connection portpassageways, wherein each keying portion comprises at least onerotationally discrete contact surface.
 28. A method for connecting afiber optic connector to a multiport assembly, the method comprising:providing a fiber optic connector comprising a ferrule and a connectorhousing, wherein the ferrule comprises an optical fiber bore and theconnector housing comprises: a rotationally discrete keying portiondefined on the outer surface of the connector housing, and arotationally discrete locking portion defined on the outer surface ofthe connector housing and interrupts the nominal housing portion as anegative cut-out, the locking portion comprising a port engagement face,wherein the port engagement face is rearwardly facing; advancing thefiber optic connector along the advancing direction into an opticalconnector port of a multiport assembly comprising at least one opticaladapter; aligning the rotationally discrete keying portion of theconnector housing with a complementary rotationally discrete keyingportion associated with the optical connector port to permit therotationally discrete locking portion of the connector housing to engagea rotationally discrete locking portion of a push-button securing memberassociated with the optical connector port; and engaging therotationally discrete locking portion of the connector housing with therotationally discrete locking portion of the push-button securing memberassociated with the optical connector port.
 29. The method of claim 28,wherein the keying portion associated with the optical connector portcomprises at least one rotationally discrete contact surface inunobstructed line of sight with an open end of a connection portpassageway of the optical connector port.
 30. The method of claim 28,wherein engaging the rotationally discrete locking portion of theconnector housing with the rotationally discrete locking portion of thepush-button securing member is subsequent to aligning the rotationallydiscrete keying portion of the connector housing with the complementaryrotationally discrete keying portion associated with the opticalconnector port.